Title :
Relationship between IBICC imaging and SEU in CMOS ICs
Author :
Sexton, F.W. ; Horn, K.M. ; Doyle, B.L. ; Laird, J.S. ; Cholewa, M. ; Saint, A. ; Legge, G.J.F.
Author_Institution :
Sandia Nat. Lab., Albuquerque, NM, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
Ion-beam-induced charge-collection imaging (IBICC) has been used to study the single event upset (SEU) mechanisms of the Sandia TA670 16-kb static random-access memory (SRAM). Quantitative charge-collection spectra from known regions of the memory cell have been derived using this technique. For 2.4-MeV He ions at normal incidence, charge collection depth for a reverse-biased p+ drain strike is estimated to be 4.8±0.4 μm. Heavy-ion strikes to the reverse-biased p-well result in nearly complete collection of deposited charge to a depth of 5.5±0.5 μm. A charge amplification effect in the n-on drain is identified and is due to either bipolar amplification or a shunt effect in the parasitic vertical npn bipolar transistor associated with the n+/n substrate, p-well, and n+drain. This effect is present only when the n+drain is at 0 V bias. When coupled with previous SEU-imaging, these results strongly suggest that the dominant SEU mechanism in this SRAM is a heavy-ion strike to the n-on transistor drain
Keywords :
CMOS integrated circuits; SRAM chips; integrated circuit testing; ion beam effects; radiation hardening (electronics); 16 kbit; 2.4 MeV; CMOS SRAM; He ions; IBICC imaging; SEU mechanism; bipolar amplification; charge amplification effect; charge collection depth; heavy ion strikes; ion beam induced charge collection imaging; parasitic vertical npn bipolar transistor; reverse biased p+ drain strike; reverse-biased p-well; shunt effect; single event upset; Circuit testing; Current measurement; Helium; Image analysis; Integrated circuit measurements; Integrated circuit modeling; Random access memory; Semiconductor device measurement; Signal analysis; Single event upset;
Journal_Title :
Nuclear Science, IEEE Transactions on
